CN211995192U - Emergency warehouse, charging rack, electric energy station and battery placing rack - Google Patents

Abstract

The utility model discloses an emergent storehouse, charging frame, electric energy station and battery rack, emergent storehouse is used for trading power station or energy storage station, be in including basic frame and setting battery package on the basic frame shifts the frame, wherein, basic frame with be provided with moving mechanism between the battery package shifts the frame, moving mechanism makes through slip or rolling form battery package shifts the frame and is in the last side direction removal along a battery package of basic frame. The utility model discloses a battery package transfer frame shifts out the battery package from basic frame rapidly to avoid the burning of thermal runaway's battery package explosion risk wave even and other battery package in the storehouse of charging. The battery pack with thermal runaway can be quickly responded and timely removed, and the risk is reduced in the shortest time.

Description

Emergency warehouse, charging rack, electric energy station and battery placing rack

Technical Field

The utility model relates to an emergent storehouse, charging frame, electric energy station and battery rack.

Background

Charging racks are generally arranged in the existing power conversion stations or energy storage stations to charge a large number of batteries. The charging rack at present is usually provided with a pure charging bin, and a battery is stored in the charging bin through a stacker crane. However, the batteries are heated during charging, if thermal runaway occurs, the thermal runaway batteries cannot be transferred to the outside of the station by a stacker crane, and once one battery burns or even explodes, other batteries are possibly ignited or even explode, so that great potential safety hazards are caused.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is that can't in time take out after the battery thermal runaway in the charging frame in order to overcome trade power station or energy storage station among the prior art, have the defect of a large amount of battery burning explosion even of ripples, provide an emergent storehouse, charging frame, electric energy station and battery rack.

The utility model discloses an above-mentioned technical problem is solved through following technical scheme:

the utility model provides an emergent storehouse for trading power station or energy storage station, emergent storehouse includes the basic frame and sets up battery package transfer frame on the basic frame, wherein, the basic frame with be provided with moving mechanism between the battery package transfer frame, moving mechanism makes through the form of sliding or rolling battery package transfer frame move along the side direction of a battery package on the basic frame.

The utility model discloses in, shift out the battery package from basic frame rapidly through battery package transfer frame to avoid the burning of thermal runaway battery package explosion risk wave even and other battery package in the storehouse of charging. Through the battery pack transfer frame correspondingly arranged on the battery pack, the battery pack with thermal runaway can be quickly responded and timely removed, and risks are reduced in the shortest time.

Preferably, the battery pack transfer frame moves on the base frame in a lateral direction of a battery pack to move the battery pack out of and separate from the base frame. The battery pack transfer frame can be pushed (in the same direction as the direction of extending out of the charging bin and placing the battery pack) by the extending mechanism of the battery transfer device (stacker), so that the battery pack transfer frame can be moved out of the emergency bin.

Preferably, the battery pack transfer frame comprises a bearing part for bearing the battery pack, a first aligning mechanism is arranged on the bearing part, a second aligning mechanism is arranged on the battery pack, and the first aligning mechanism and the second aligning mechanism are matched with each other so as to limit the battery pack on the bearing part in the length direction and/or the width direction of the battery pack. The first aligning mechanism and the second aligning mechanism can limit the battery pack, so that the battery pack can be stably fixed on the battery pack transfer frame. The battery pack transfer device is convenient for placing the battery pack on the battery pack transfer frame, and meanwhile, the battery pack is not easy to drop in the movement of the battery pack transfer frame.

Preferably, the battery pack is placed in and moved out of the battery pack transfer frame in an up-down direction, wherein the first aligning mechanism and the second aligning mechanism are engaged or disengaged in the up-down direction. The first aligning mechanism and the second aligning mechanism which are matched in the up-down direction do not influence the taking and placing of the battery pack, and meanwhile, the battery pack is limited and fixed in the translation process of the battery pack.

Preferably, the first aligning mechanism is a guide fork or an aligning block, and the second aligning mechanism is a correspondingly arranged aligning block or a guide fork; the alignment block is clamped into a clamping groove between two forks of the guide fork to be matched, so that the battery pack is limited in the length direction and the width direction of the battery pack. Two forks of the guide fork are clamped on two sides of the alignment block, so that the battery pack is limited in the length direction. Meanwhile, the guide fork is clamped on the two sides of the battery pack transfer frame or the battery pack in the width direction, so that the battery pack is limited in the width direction.

Preferably, the top of at least one of the two prongs of the guide prong has a slope or arc surface facing the inside of the guide prong. The inclined surface or the cambered surface arranged here can guide the battery pack to be smoothly placed into or moved out of the battery pack transfer frame.

Preferably, the tops of the two forks of the guide fork are turned outwards towards the outer side of the emergency bin. The outward-turned guide fork provides the alignment adjustment performance in the width direction of the battery pack, so that the tolerance of the bearing mechanism is better, and the battery pack can be smoothly moved into or out of the battery pack transfer frame.

Preferably, two sides of the carrying part are respectively provided with a third alignment mechanism, and the third alignment mechanism and the side surface of the battery pack are mutually matched so as to limit the battery pack on the carrying part in the width direction of the battery pack. The third aligning mechanism further limits the battery pack. Wherein, under the spacing circumstances of first counterpoint mechanism and second counterpoint mechanism at the length of battery package and two dimensions of width direction, it is spacing to add a dimension of the width direction of third counterpoint mechanism to the battery package, makes two counterpoint points increase for the counterpoint face that has four counterpoint points, increases the counterpoint accuracy and the success rate that the battery package placed the entering.

Preferably, the top of the third aligning mechanism is turned outwards towards the outer side of the emergency bin. The third alignment mechanism which is turned outwards provides alignment adjustability in the width direction of the battery pack and is also beneficial to the smooth movement of the battery pack into or out of the battery pack transfer frame.

Preferably, the moving mechanism comprises a track surface arranged on the base frame and a roller or a roller arranged on the battery pack transfer frame; or the moving mechanism comprises a roller or a roller arranged on the base frame and a track surface arranged on the battery pack transfer frame. The moving mechanism adopts the matching of the roller or the roller and the track surface, so that the sliding friction and the abrasion of parts between the battery pack transfer frame and the base frame can be reduced, and the battery pack transfer frame can move more quickly and smoothly.

Preferably, the battery pack transfer frame comprises a front beam and a rear beam, and the front beam and the rear beam are respectively movably arranged with the base frame through the moving mechanism. The moving mechanisms are arranged on the front beam and the rear beam, so that the battery pack transfer frame can move on the base frame more uniformly.

Preferably, the moving mechanism comprises track surfaces arranged at the bottoms of the front beam and the rear beam and rollers or rollers arranged at the tops of the front chassis and the rear chassis of the basic frame and matched with the front chassis and the rear chassis of the basic frame; or the moving mechanism comprises rollers or rollers arranged at the bottoms of the front beam and the rear beam and track surfaces arranged at the tops of the front underframe and the rear underframe of the basic frame and matched with the front underframe and the rear underframe. The moving mechanism is arranged between the front beam, the rear beam and the base frame, and the matching of the roller or the roller and the track surface is adopted, so that the battery pack transfer frame can move on the base frame more balance, the sliding friction between the battery pack transfer frame and the base frame can be reduced, and the battery pack transfer frame can move more quickly and smoothly.

Preferably, the moving mechanism further comprises rollers or rollers arranged on the side surfaces of the front beam and the rear beam, and track surfaces arranged on the side surfaces of the front side frame and the rear side frame of the base frame and matched with the side surfaces of the front side frame and the rear side frame; or the moving mechanism further comprises track surfaces arranged on the side surfaces of the front beam and the rear beam, and rollers or rollers arranged on the side surfaces of the front side frame and the rear side frame of the base frame and matched with the side surfaces of the front side frame and the rear side frame. The idler wheels or the rollers arranged on the side face are beneficial to limiting in the direction vertical to the moving-out direction of the battery pack, and the friction force is reduced in the moving-out direction of the battery pack.

Preferably, the roller is a grooved wheel, and the track surface has a protrusion or a raised rail which is matched with a groove of the grooved wheel. The roller arranged on the side surface is matched with the bulge or the convex rail through the groove in the grooved wheel, so that the bulge and the convex rail limit the roller in the vertical direction to avoid the separation of the roller.

Preferably, the two sides of the front beam are respectively provided with a first aligning mechanism, the two sides of the battery pack are provided with a second aligning mechanism, the two sides of the rear beam are respectively provided with a third aligning mechanism, the battery pack transfer frame comprises a bearing part for bearing the battery pack, the first aligning mechanism and the second aligning mechanism are mutually matched so that the battery pack is limited on the bearing part in the length direction and/or the width direction of the battery pack, and the third aligning mechanism and the side surface of the battery pack are mutually matched so that the battery pack is limited on the bearing part in the width direction of the battery pack.

A charging rack comprises a plurality of charging bins and the emergency bin. Through set up emergent storehouse on the charging frame, can respond rapidly and in time remove the battery package of thermal runaway from the charging frame, reduce the whole risk of charging frame in the shortest time.

Preferably, the charging rack further comprises a fixing column extending along the vertical direction; the charging bin comprises a bearing mechanism for bearing the battery pack through a frame structure; the bearing mechanism of the charging bin and the base frame of the emergency bin are respectively connected to the fixing column. Emergent storehouse and the one set of fixed column of storehouse sharing that charges, the position that only occupies a storehouse of charging in emergency storehouse is equivalent to, need not to set up the emergent storehouse of fixed column installation in addition, the emergent storehouse of being convenient for installation on the charging frame.

Preferably, a hollow frameless space is formed in the bearing mechanism, and the frameless space is used for the extending mechanism of the battery pack transfer device to extend into and place the battery pack. The bearing mechanism is arranged into a hollow frameless space, so that the distance between the two charging bins can be reduced in the vertical direction, and the overall occupied space of the charging frame is reduced.

The utility model provides an electric energy station, the electric energy station is for trading power station or energy storage station, be provided with in the electric energy station the charging frame, the electric energy station is close to be provided with open and close formula door on the lateral wall in emergent storehouse, but open and close formula door is used for supplying to bear the weight of the battery package transfer frame shifts out the electric energy station. Set up emergent storehouse on trading the charging frame in power station or the energy storage station, set up open-close formula storehouse door in the position that the lateral wall of station corresponds emergent storehouse simultaneously, can take place to move out the battery package outside the station rapidly when the battery package in the station takes place the thermal runaway to avoid the burning of the battery package of thermal runaway even explosion risk to spread other battery packages and facilities etc. in the station.

Preferably, the inner side of the openable bin gate is provided with a buffer strip. The buffer strips are arranged to absorb the impact force on the openable bin door when the battery pack transfer frame moves out, so that the openable bin door and/or the battery pack are protected.

Preferably, the outside of electric energy station is provided with the battery rack, the battery rack with but emergent storehouse corresponds the setting and is located respectively but the inside and outside both sides of open and close formula door, wherein, the battery rack have with the same basic frame and moving mechanism in emergent storehouse. Set up the battery rack outside the station in order to conveniently handle the battery package of releasing to the station outside, the battery rack have with the same basic frame and moving mechanism in emergent storehouse make things convenient for battery package transfer frame to directly move to the battery rack from the station.

Preferably, the moving mechanism of the battery rack and the moving mechanism of the emergency bin are collinear in the direction of moving out the battery pack, so that the battery pack transfer frame moves between the base frame of the battery rack and the base frame of the emergency bin.

The utility model provides a battery rack for set up the station outside that corresponds the position in the emergent storehouse of electric energy station, battery rack has the basic frame and the moving mechanism in emergent storehouse. The base frame on the battery placing frame can quickly bear the battery pack transferring frame which is moved out from the station, so that the battery pack can be rapidly moved from the base frame to the station and go out, and the burning and even explosion risks of the battery pack out of control due to heat are avoided from affecting other battery packs in the charging bin in the station.

The utility model discloses an actively advance the effect and lie in: the utility model discloses a battery package transfer frame shifts out the battery package from basic frame rapidly to avoid the burning of thermal runaway's battery package explosion risk wave even and other battery package in the storehouse of charging. The battery pack with thermal runaway can be quickly responded and timely removed, and the risk is reduced in the shortest time.

Drawings

Fig. 1 is a schematic structural diagram of a charging stand according to a preferred embodiment of the present invention.

Fig. 2 is a schematic structural view of an emergency cabin according to a preferred embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a base frame according to a preferred embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a battery pack transfer frame according to a preferred embodiment of the present invention.

Fig. 5 is a schematic perspective view of a guide fork according to a preferred embodiment of the present invention.

Fig. 6 is a schematic side view of a guide fork according to a preferred embodiment of the present invention.

Fig. 7 is a schematic diagram of a limiting structure of a battery pack according to a preferred embodiment of the present invention.

Fig. 8 is a schematic view of the positions of the emergency bin and the openable bin door according to the preferred embodiment of the present invention.

Fig. 9 is a schematic position diagram of the battery holder and the openable bin gate according to the preferred embodiment of the present invention.

Fig. 10 is a schematic structural view of a battery holder according to a preferred embodiment of the present invention.

Detailed Description

The present invention is further illustrated by way of the following examples, which are not intended to limit the scope of the invention.

As shown in fig. 1 to 10, the present embodiment discloses an emergency cabin 1, a charging stand, a power station, and a battery rack 2. As shown in fig. 1 to 4, the embodiment discloses an emergency cabin 1 for a power conversion station or an energy storage station, the emergency cabin 1 includes a base frame 11 and a battery pack transfer frame 12 disposed on the base frame 11, wherein a moving mechanism (including a roller 31 and a roller 32) is disposed between the base frame 11 and the battery pack transfer frame 12, and the moving mechanism enables the battery pack transfer frame 12 to move on the base frame 11 along a side direction of a battery pack 8 in a sliding or rolling manner.

The utility model discloses in, shift frame 12 through the battery package and shift out battery package 8 from basic frame 11 rapidly to avoid the burning of thermal runaway's battery package 8 explosion risk ripples even and other battery package 8 in the storehouse of charging 4. Through the battery pack transfer frame 12 correspondingly arranged on the battery pack 8, the battery pack 8 with thermal runaway can be quickly responded and timely removed, and the risk is reduced in the shortest time.

As shown in fig. 1, 7 and 8, the battery pack transfer frame 12 of the present embodiment is moved on the base frame 11 in a lateral direction of a battery pack 8 to move the battery pack 8 out of and separate from the base frame 11. The extending mechanism based on the conventional battery pack transfer device generally extends and contracts in the width direction of the battery pack 8, so the lateral direction of the battery pack 8 of the present embodiment is specifically the width direction of the battery pack 8, and in other embodiments, the lateral direction may be set to be the length direction of the battery pack 8. When moving, the battery pack transfer frame 12 can be pushed (in the same direction as the direction in which the battery pack 8 is extended to the charging bin 4) by the extension mechanism of the battery transfer device (stacker), so that the battery pack transfer frame 12 moves out of the emergency bin 1.

As shown in fig. 2 and fig. 4, the battery pack transfer frame 12 of the present embodiment includes a carrying portion (including a front beam 121 and a rear beam 122) for carrying the battery pack 8, the carrying portion is provided with a first aligning mechanism 61, the battery pack 8 is provided with a second aligning mechanism 62, and the first aligning mechanism 61 and the second aligning mechanism 62 are mutually matched to limit the battery pack 8 on the carrying portion in the length and/or width direction of the battery pack 8 (in the present embodiment, the first aligning mechanism and the second aligning mechanism are arranged in the length and width direction of the battery pack 8 at the same time). First counterpoint mechanism 61 and second counterpoint mechanism 62 can carry on spacingly to battery package 8 for battery package 8 can be stable fix on battery package transfer frame 12. The battery pack 8 is also not easily dropped during the movement of the battery pack transfer frame 12.

In this embodiment, the battery pack 8 is placed and moved out of the battery pack transfer frame 12 in the up-down direction, in which the first aligning mechanism 61 and the second aligning mechanism 62 are engaged or disengaged in the up-down direction. The first aligning mechanism 61 and the second aligning mechanism 62 which are matched in the up-down direction do not influence the taking and placing of the battery pack 8, and meanwhile, the battery pack 8 is limited and fixed in the translation process of the battery pack 8.

As shown in fig. 5, 6 and 7, the first aligning mechanism 61 of the present embodiment is a guide fork, and the second aligning mechanism 62 is a correspondingly disposed aligning block; the alignment block of the second alignment mechanism 62 is clamped into the clamping groove 611 between the two forks 612 of the guide fork of the first alignment mechanism 61 to be matched, so as to limit the battery pack 8 in the length and width directions of the battery pack 8. In other embodiments, the first alignment mechanism 61 may be an alignment block, and the second alignment mechanism 62 may be a correspondingly disposed guide fork; further, other mating structures, such as mating structures of sockets and pins, etc., are not excluded.

As shown in fig. 5 and 7, the two forks 612 of the guide fork of the first aligning mechanism 61 of the present embodiment are caught at both sides of the aligning block of the second aligning mechanism 62, thereby performing a limit in the length direction of the battery pack 8. Meanwhile, the two guide forks are clamped on two sides of the battery pack transfer frame 12 or the battery pack 8 in the width direction, so that the battery pack 8 is limited in the width direction.

As shown in fig. 5 and 6, the tops of the two forks 612 of the guide fork of the first aligning mechanism 61 of the present embodiment have slopes or curved surfaces toward the inside of the guide fork. The slope or curve provided here can guide the battery pack 8 smoothly into or out of the battery pack transfer frame 12. In this embodiment, the tops of the two forks 612 of the guide fork of the first aligning mechanism 61 are turned outwards in the outside direction of the emergency bin 1. In other embodiments, one of the prongs 612 may have a slope or a curved surface facing the inside of the guide prong and turned outwards in the direction of the outside of the emergency bin 1. The guide fork turned outwards makes the tolerance of the bearing mechanism better, and further facilitates the smooth moving of the battery pack into or out of the battery pack transfer frame.

As shown in fig. 4 and 7, the third alignment mechanism 63 is disposed on each of two sides of the supporting portion, and the third alignment mechanism 63 and the side surface of the battery pack 8 are engaged with each other to limit the battery pack 8 on the supporting portion in the width direction of the battery pack 8. The third aligning mechanism 63 further limits the battery pack 8. In this embodiment, under the condition that the first aligning mechanism 61 and the second aligning mechanism 62 are limited in the two dimensions in the length and width directions of the battery pack 8, the third aligning mechanism 63 is limited in only one dimension in the width direction of the battery pack 8, so that the success rate of placing the battery pack 8 into the battery pack is increased. Two alignment points are increased to be alignment surfaces with four alignment points, and alignment accuracy and success rate of placing and entering of the battery pack are increased.

In this embodiment, the top of the third alignment mechanism 63 is also arranged to be turned outwards in the direction of the outside of the emergency bin 1. The third outwardly turned aligning mechanism 63 also has a function of making the tolerance of the carrying mechanism better, facilitating smooth movement of the battery pack 8 into and out of the battery pack transfer frame 12.

As shown in fig. 3 and 4, the moving mechanism of the present embodiment includes track surfaces of side surfaces and bottom surfaces of the front beam 121 and the rear beam 122 provided on the battery pack transfer frame 12, and a roller 31 and a roller 32 (or a roller) provided on the base frame 11. In other embodiments, the moving mechanism may also include a roller or a roller disposed on the battery pack transfer frame 12 and a track surface disposed on the base frame 11. The moving mechanism adopts the matching of the roller 31 and the roller 32 (roller) or the rail surface, so that the sliding friction between the battery pack transfer frame 12 and the base frame 11 can be reduced, and the battery pack transfer frame 12 can move more quickly and smoothly.

As shown in fig. 3 and 4, the battery pack transfer frame 12 of the present embodiment includes a front beam 121 and a rear beam 122, and the front beam 121 and the rear beam 122 are respectively movably disposed with the base frame 11 by a moving mechanism. The base frame 11 includes a front base frame 111 and a rear base frame 112, which correspond to the front beam 121 and the rear beam 122, respectively. The moving mechanism is provided on each of the front beam 121 and the rear beam 122, so that the battery pack transfer frame 12 can move on the base frame 11 more evenly.

As shown in fig. 3 and 4, the moving mechanism of the present embodiment includes track surfaces disposed at the bottoms of the front beam 121 and the rear beam 122, and rollers 31 disposed at the tops of the front chassis 1111 and the rear chassis 1121 of the base frame 11 and engaged therewith. In other embodiments, the moving mechanism may also include rollers or rollers disposed at the bottom of the front beam 121 and the rear beam 122 and track surfaces disposed at the top of the front chassis 1111 and the rear chassis 1121 of the base frame 11 to cooperate therewith. The moving mechanism is arranged between the front beam 121, the rear beam 122 and the base frame 11, and the cooperation of the roller or the roller and the track surface is adopted, so that the battery pack transfer frame 12 can move on the base frame 11 more in a balanced manner, the sliding friction between the battery pack transfer frame 12 and the base frame 11 can be reduced, and the movement of the battery pack transfer frame 12 is faster and smoother.

As shown in fig. 3 and 4, the moving mechanism of the present embodiment further includes rollers 32 disposed on the side surfaces of the front beam 121 and the rear beam 122, and track surfaces disposed on the side surfaces of the front side frame 1112 and the rear side frame 1122 of the base frame 11 and matched with the side surfaces. The laterally arranged rollers 32 or rollers facilitate the limiting in the direction perpendicular to the direction of removal of the battery pack 8 and reduce the friction in the direction of removal of the battery pack 8. In other embodiments, the moving mechanism may also include track surfaces disposed on the sides of the front beam 121 and the rear beam 122, and rollers 32 or rollers disposed on the sides of the front side frame 1112 and the rear side frame 1122 of the base frame 11 to cooperate therewith.

In this embodiment, the roller 32 is preferably a sheave, and the orbital surface has a projection or a raised rail that mates with a groove of the sheave. The laterally disposed rollers engage the protrusions or raised rails through the grooves in the grooved wheels, whereby the protrusions and raised rails restrain the rollers 32 in a vertical direction to prevent the rollers 32 from disengaging.

As shown in fig. 4, two sides of the front beam 121 of the present embodiment are respectively provided with a first alignment mechanism 61, two sides of the battery pack 8 are provided with a second alignment mechanism 62, two sides of the rear beam 122 are respectively provided with a third alignment mechanism 63, the battery pack transfer frame 12 includes a bearing portion for bearing the battery pack 8, wherein the first alignment mechanism 61 and the second alignment mechanism 62 are mutually matched so as to limit the battery pack 8 on the bearing portion in the length direction and/or the width direction of the battery pack 8, and the third alignment mechanism 63 and the side surface of the battery pack 8 are mutually matched so as to limit the battery pack 8 on the bearing portion in the width direction of the battery pack 8.

As shown in fig. 1, the embodiment also discloses a charging rack, which comprises a plurality of charging bins 4 and an emergency bin 1. The charging bin 4 and the emergency bin 1 on the charging rack in fig. 1 of the present embodiment are arranged in a vertical direction, and in other embodiments, may be arranged in a horizontal direction, an array, or other various alternative arrangements. Through set up emergent storehouse 1 on the charging frame, can respond rapidly and in time remove battery package 8 that the thermal runaway from the charging frame, reduce the whole risk of charging frame in the shortest time.

In this embodiment, the base frame 11 of the emergency cabin 1 is preferably provided with a limiting block at the insertion side of the battery pack 8 (the insertion side of the battery pack usually means that the extending mechanism of the battery transfer device (stacker) extends into the inlet side of the battery pack transfer frame 12), and the limiting block is arranged corresponding to the front beam 121 and the rear beam 122 of the battery pack transfer frame 12 to prevent the battery pack transfer frame 12 from sliding out of the insertion side of the battery pack 8.

As shown in fig. 1 and 8, the charging stand of the present embodiment further includes a fixing post 5 extending in a vertical direction; the charging bin 4 comprises a carrying mechanism 41 for carrying the battery pack 8 by means of a frame structure; the bearing mechanism 41 of the charging bin 4 and the base frame 11 of the emergency bin 1 are respectively connected to the fixing column 5. In this embodiment, one set of fixed column 5 of emergent storehouse 1 and 4 sharings in storehouse of charging is equivalent to emergent storehouse 1 and only occupies the position of a storehouse of charging 4, need not to set up in addition emergent storehouse 1 of column mouting, the installation of emergent storehouse 1 on the charging frame of being convenient for.

As shown in fig. 1, a hollow frameless space 42 is formed in the carrying mechanism 41 for carrying the battery pack 8, and the frameless space 42 is used for the extension mechanism of the battery pack 8 transportation device to extend into the battery pack 8. The frameless space 42 shown in fig. 1 is generally rectangular. In other embodiments, different shapes may be provided as desired. In this embodiment, the bearing mechanism 41 of the charging bin 4 is configured as a hollow frameless space 42, and the distance between two charging bins 4 can be reduced in the vertical direction, so as to reduce the overall occupied space of the charging rack.

The embodiment also discloses an electric energy station which is a power exchanging station or an energy storage station. Fig. 8 shows an internal schematic view of the power station. A charging frame is arranged in the electric energy station, an openable bin door 7 is arranged on the side wall of the electric energy station close to the emergency bin 1, and the openable bin door 7 is used for enabling a battery pack transfer frame 12 bearing a battery pack 8 to move out of the electric energy station. Set up emergent storehouse 1 on trading the charging frame in power station or the energy storage station, but set up open closed door 7 in the lateral wall of station corresponding position in emergent storehouse 1 simultaneously, can shift out battery package 8 outside the station rapidly when battery package 8 in the station takes place the thermal runaway to avoid the burning of battery package 8 of thermal runaway even explosion risk to spread other battery package 8 and facilities etc. in the station.

As shown in fig. 8, the inside of the openable and closable bin door 7 of the present embodiment is provided with a buffer strip 71. When the thermal runaway of the battery pack 8 occurs, the battery pack transfer frame 12 pushes open the openable bin gate 7 together with the battery pack 8. At this time, the buffer bar 71 can absorb the impact on the openable and closable compartment door 7 when a part of the battery pack transfer frame 12 is removed, reduce the impact when pushed open, and protect the openable and closable compartment door 7 and/or the battery pack 8.

As shown in fig. 9, which is an external schematic view of an electric energy station, a battery placing rack 2 is arranged on the outer side of the electric energy station, the battery placing rack 2 is arranged corresponding to an emergency bin 1 and is respectively located on the inner side and the outer side of an openable bin door 7, wherein the battery placing rack 2 has a base frame 21 and a moving mechanism which are the same as those of the emergency bin 1. The battery placing frame 2 is arranged outside the station to facilitate disposal of battery packs pushed out of the station, the battery placing frame 2 is provided with a base frame 21 and a moving mechanism which are the same as those of the emergency bin, and the battery pack transferring frame 12 is convenient to directly move from the station to the battery placing frame 2.

As shown in fig. 10, the base frame 21 of the battery rack 2 includes a front base frame 211 and a rear base frame 212. After the battery pack transfer frame 12 is moved out of the base frame 11 in fig. 8 to the base frame 21 of the battery rack 2 in fig. 9, the front beam 121 and the rear beam 122 correspond to the front base frame 211 and the rear base frame 212, respectively.

As shown in fig. 10, the moving mechanism of the battery rack 2 includes rail surfaces disposed at the bottoms of the front beam 121 and the rear beam 122, and rollers 33 disposed at the tops of the front chassis 2111 and the rear chassis 2121 of the base frame 21 to be engaged therewith. In other embodiments, the moving mechanism may also include rollers or rollers disposed at the bottom of the front beam 121 and the rear beam 122 and track surfaces disposed at the top of the front chassis 2111 and the rear chassis 2121 of the base frame 21 for cooperating therewith.

As shown in fig. 10, the moving mechanism of the battery rack 2 further includes rollers 32 disposed on the side surfaces of the front beam 121 and the rear beam 122, and rail surfaces disposed on the side surfaces of the front side frame 2112 and the rear side frame 2122 of the base frame 21 and matched with the side surfaces. The laterally arranged rollers 32 or rollers facilitate the limiting in the direction perpendicular to the direction of removal of the battery pack 8 and reduce the friction in the direction of removal of the battery pack 8. In other embodiments, the moving mechanism may also include track surfaces disposed on the sides of the front beam 121 and the rear beam 122, and rollers 32 or rollers disposed on the sides of the front side frame 2112 and the rear side frame 2122 of the base frame 21 to cooperate with the track surfaces.

In this embodiment, the moving mechanism of the battery rack 2 and the moving mechanism of the emergency cabin 1 are collinear in the moving direction of the battery pack 8, so that the battery pack transfer frame 12 can be rapidly moved between the base frame 21 of the battery rack 2 and the base frame 11 of the emergency cabin 1.

As shown in fig. 10, a battery rack 2 of the present embodiment is provided outside a station at a position corresponding to an emergency room 1 of an electric power station, and the battery rack 2 has a base frame 21 and a moving mechanism of the emergency room 1. The bottom of the battery placing frame 2 is provided with a containing cavity 22, and the containing cavity 22 inclines towards one side far away from the openable bin door 7. The falling object generated by the combustion of the battery pack 8 falls into the accommodation chamber 22 and is away from the openable bin door 7, thereby increasing the safety. In addition, in order to prevent the battery pack transfer frame 12 from being directly pushed away from the base frame of the battery rack by an excessive pushing force when being pushed out from the station, a limiting plate is preferably arranged on the base frame of the battery rack, and the limiting plate is arranged on one side, away from the electric energy station, of the base frame of the battery rack.

The utility model discloses basic frame on the battery rack can bear the battery package transfer frame that shifts out in the slave station fast to the realization moves battery package slave station inside to outside the station rapidly, thereby avoids the burning of thermal runaway battery package to explode the risk even and reach other battery packages in the station. The battery pack which is out of thermal runaway is quickly responded and removed in time, and risks in the electric power station can be reduced in the shortest time.

Although specific embodiments of the present invention have been described above, it will be understood by those skilled in the art that this is by way of example only and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and the principles of the present invention, and these changes and modifications are all within the scope of the present invention.

Claims (23)

1. An emergency bin for a battery replacing station or an energy storage station, which is characterized in that the emergency bin comprises a base frame and a battery pack transfer frame arranged on the base frame, wherein a moving mechanism is arranged between the base frame and the battery pack transfer frame, and the moving mechanism enables the battery pack transfer frame to move along the side direction of a battery pack on the base frame in a sliding or rolling manner.

2. An emergency hatch according to claim 1, wherein said battery pack transfer frame is moved on said base frame in a lateral direction of a battery pack to move said battery pack out of and away from said base frame.

3. The emergency bin of claim 1, wherein the battery pack transfer frame comprises a bearing part for bearing the battery pack, a first aligning mechanism is arranged on the bearing part, a second aligning mechanism is arranged on the battery pack, and the first aligning mechanism and the second aligning mechanism are matched with each other to limit the battery pack on the bearing part in the length direction and/or the width direction of the battery pack.

4. The emergency bin of claim 3, wherein the battery pack is placed and removed from the battery pack transfer frame in an up-and-down direction, and wherein the first aligning mechanism and the second aligning mechanism are engaged or disengaged in the up-and-down direction.

5. The emergency bin of claim 3, wherein the first aligning mechanism is a guide fork or an aligning block, and the second aligning mechanism is a correspondingly arranged aligning block or a guide fork; the alignment block is clamped into a clamping groove between two forks of the guide fork to be matched, so that the battery pack is limited in the length direction and the width direction of the battery pack.

6. An emergency magazine according to claim 5, wherein the top of at least one of the two tines of the guide fork has a bevel or camber facing inwardly of the guide fork.

7. An emergency compartment according to claim 5 wherein the two prong tops of the guide prong are turned outwards in the direction of the outside of the emergency compartment.

8. An emergency bin according to claim 3, wherein the two sides of the bearing part are respectively provided with a third alignment mechanism, and the third alignment mechanism and the side surface of the battery pack are mutually matched so as to limit the battery pack on the bearing part in the width direction of the battery pack.

9. An emergency bin according to claim 8, wherein the top of the third aligning device is turned outwards in the direction of the outside of the emergency bin.

10. The emergency bin of claim 1, wherein the moving mechanism comprises a track surface disposed on the base frame and a roller or drum disposed on the battery pack transfer frame; or the moving mechanism comprises a roller or a roller arranged on the base frame and a track surface arranged on the battery pack transfer frame.

11. The emergency bin of claim 10, wherein the battery pack transfer frame comprises a front beam and a rear beam, and the front beam and the rear beam are movably disposed with the base frame by the moving mechanism, respectively.

12. The emergency bin of claim 11, wherein the moving mechanism comprises a track surface arranged at the bottom of the front beam and the rear beam and a roller or a roller arranged at the top of the front chassis and the rear chassis of the base frame and matched with the front chassis and the rear chassis; or the moving mechanism comprises rollers or rollers arranged at the bottoms of the front beam and the rear beam and track surfaces arranged at the tops of the front underframe and the rear underframe of the basic frame and matched with the front underframe and the rear underframe.

13. The emergency cabin according to claim 12, wherein the moving mechanism further comprises rollers or rollers disposed at the side surfaces of the front beam and the rear beam, and rail surfaces disposed at the side surfaces of the front side frame and the rear side frame of the base frame and matched with the rollers or rollers; or the moving mechanism further comprises track surfaces arranged on the side surfaces of the front beam and the rear beam, and rollers or rollers arranged on the side surfaces of the front side frame and the rear side frame of the base frame and matched with the side surfaces of the front side frame and the rear side frame.

14. The emergency bin of claim 13, wherein the roller is a sheave and the track surface has a protrusion or a raised rail that mates with a groove of the sheave.

15. The emergency bin according to claim 11, wherein the front beam is provided with first aligning mechanisms at two sides thereof, the battery pack is provided with second aligning mechanisms at two sides thereof, the rear beam is provided with third aligning mechanisms at two sides thereof, and the battery pack transfer frame comprises a bearing part for bearing the battery pack, wherein the first aligning mechanisms and the second aligning mechanisms are matched with each other to limit the battery pack on the bearing part in the length direction and/or the width direction of the battery pack, and the third aligning mechanisms and the side surfaces of the battery pack are matched with each other to limit the battery pack on the bearing part in the width direction of the battery pack.

16. A charging stand comprising a plurality of charging bays and an emergency bay according to any of claims 1 to 15.

17. The charging stand according to claim 16, further comprising a fixing post extending in a vertical direction; the charging bin comprises a bearing mechanism for bearing the battery pack through a frame structure; the bearing mechanism of the charging bin and the base frame of the emergency bin are respectively connected to the fixing column.

18. The charging rack according to claim 17, wherein the carrying mechanism forms a hollow frameless space therein, and the frameless space is used for the extension mechanism of the battery pack transfer device to extend into and place the battery pack.

19. An electric energy station, which is a battery replacement station or an energy storage station, wherein a charging rack according to any one of claims 16 to 18 is arranged in the electric energy station, and an openable and closable compartment door is arranged on a side wall of the electric energy station close to the emergency compartment, and is used for moving the battery pack transfer frame carrying the battery pack out of the electric energy station.

20. The electrical power station of claim 19, wherein the inside of the openable door is provided with a buffer strip.

21. The electric power station of claim 19, wherein a battery placing rack is arranged on the outer side of the electric power station, the battery placing rack is arranged corresponding to the emergency bin and is respectively arranged on the inner side and the outer side of the openable bin door, and the battery placing rack has the same basic frame and moving mechanism as the emergency bin.

22. The power station of claim 21, wherein the movement mechanism of the battery rack and the movement mechanism of the emergency bin are collinear in a direction along which the battery pack is removed, such that the battery pack transfer frame moves between the base frame of the battery rack and the base frame of the emergency bin.

23. A battery rack for being arranged outside an emergency room of an electric power station, wherein the battery rack has a base frame and a moving mechanism of the emergency room as claimed in any one of claims 1 to 18.

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